Substrate holding system and exposure apparatus using the same

ABSTRACT

Disclosed is a unique and improved substrate holding technique in accordance with an aspect of which there is provided a substrate holding system having a chuck for vacuum attraction and electrostatic attraction of a substrate, and including a ring-like rim for carrying a substrate thereon, a plurality of first protrusions disposed inside the rim, for carrying the substrate thereon, and a plurality of second protrusions disposed inside the rim, for carrying the substrate thereon, wherein a substrate carrying surface area of at least one first protrusion is smaller than a substrate carrying surface area of at least one second protrusion and wherein a smallest interval of the first protrusions is smaller than a smallest interval of the second protrusions.

FIELD OF THE INVENTION AND RELATED ART

This invention relates to a substrate holding technique suitable for safely and securely holding even a warped substrate. More particularly, the invention concerns s substrate holding technique suitably usable in an apparatus, such as a semiconductor exposure apparatus using extreme ultraviolet (EUV) light or charged-particle beam, wherein a substrate is processed in a vacuum or reduced pressure ambience.

The density and fineness of semiconductor devices are advancing much more, and a substrate holding system is required to have a capability of holding a substrate at higher precision. If the substrate holding precision is insufficient, a printed pattern or an overlay precision is degraded.

Conventionally, a substrate such as a waver is held in accordance with a mechanical holding method or a vacuum attraction holding method.

The mechanical holding method is a simplest method in which only an outside peripheral portion of a wafer is physically clamped. Although it has a feature of being less susceptive to the influence of environment, since only the wafer outer periphery is held, there is a problem of deformation of the wafer or damaging the wafer.

The method based on vacuum attraction is a method in which the bottom face of a wafer is supported by many protrusions and a negative pressure is created in the clearance between the wafer and a substrate attracting device, by which the wafer is attracted. As compared with the mechanical holding method, this method is advantageous in the point of suppressing wafer deformation because the whole wafer surface is attracted. However, this method can not be used in a vacuum ambience, and it can not be applied to apparatuses using vacuum.

On the other hand, there is a method based on an electrostatic force. Since this method uses electrostatic force, it can be used even in a vacuum or reduced pressure ambience. Thus, actually it is applied to various device manufacturing processes such as etcher, PVD or CVD. In regard to exposure apparatuses, particularly, in electron beam exposure apparatus or EUV exposure apparatus, the exposure process has to be carried out in a vacuum ambience to avoid attenuation of electron beam or EUV light. Thus, in such apparatuses, use of a substrate holding system based on electrostatic force is considered as a requisite.

Substrates such as wafers to be processed in semiconductor manufacturing steps are not always plane, and in some cases they may have a large warp as a result of a film forming process, for example.

Conventionally, an attraction force can be applied to the whole wafer surface by vacuum attraction such that the warp of the wafer can be corrected thereby. However, as described, this technique can not be used in a system operated in a vacuum ambience.

On the other hand, electrostatic attraction can not easily meet such warp of wafer as compared with the vacuum attraction. For, generally, in a substrate holding system, the contact surface to a wafer is limited so as to prevent degradation of the flatness due to bite of particles. In the electrostatic attraction, basically the attraction force is produced at the contact surface.

To avoid this problem, Japanese Laid-Open Patent Application, Publication No. 6-204325 proposes an electrostatic attracting device having stripe-like electrodes and means for applying a voltage to each electrode independently. For example, voltages are applied sequentially to these electrode in an order from a central electrode to a peripheral electrode or from one end electrode to the other end electrode, for example, to ensure that a warped wafer sequentially follow the substrate attracting device. With this method, if a wafer is warped parabolic as like upward convex or downward convex, the flatness correction may be attainable. However, if a wafer is warped irregularly, correction is difficult to achieve.

Furthermore, after the wafer flatness correction, the wafer must be conveyed to a substrate processing chamber while holding the corrected state. Japanese Patent No. 2633516 discloses a method in which a substrate is attracted onto an electrostatic attraction device outside a substrate processing chamber and it is conveyed into the substrate processing chamber. In accordance with this patent document, however, the voltage supply to the electrostatic attraction device is once interrupted during the conveyance. Therefore, the substrate flatness correction is discontinued during the conveyance. Here, the substrate processing chamber may be, for example, an exposure chamber in the case of an exposure apparatus.

Japanese Laid-Open Patent Application, Publication No. 2003-142393 discloses a method in which, by use of a substrate attracting device having a vacuum attracting mechanism and an electrostatic attracting mechanism, a substrate is flatness-corrected by vacuum attraction outside a substrate processing chamber (load lock chamber, for example), and thereafter the attraction is changed to electrostatic attraction and the substrate is conveyed into the substrate processing chamber. More specifically, in a load lock chamber which is separate from the substrate processing chamber, first only the clearance between the substrate and the substrate attracting device is exhausted and, after the substrate is vacuum attracted, a voltage is applied to a chuck to change the attraction to electrostatic attraction. Thereafter, the clearance between the substrate and the substrate attracting device is opened to the atmosphere to release the vacuum attraction. Subsequently, vacuum is introduced into the load lock chamber until the inside pressure thereof becomes approximately equal to that of the substrate processing chamber.

Here, the pressure changes through a low discharge generating voltage region of a Paschen's electric discharge voltage graph shown in FIG. 11, that is, i.e., through a minimum value (Vs(MIN)) region. Therefore, an electric discharge can easily occur between the substrate and the substrate attracting device to which the voltage is being applied. For example, if the clearance between the substrate and the substrate attracting device is 100 im, as shown in FIG. 11, the discharge voltage takes a minimum value 300 V at a pressure 7 [kPa]. Therefore, if the pressure of the clearance is lowered from the atmospheric pressure (101 [kPa]) to the substrate processing chamber pressure (not greater than 1 [kPa]), the change inevitably passes the minimum value and the electric discharge quite easily occurs. If an electric discharge occurs between the substrate and the substrate attracting device, it may cause damage of the substrate or breakage of devices on the substrate. Furthermore, the discharge may create dust particles which contaminate the substrate and the substrate attracting device. In consideration of this, according to this patent document, a low voltage is applied to the chuck so as to avoid occurrence of electric discharge phenomenon during exhaust of the load lock chamber.

However, if the voltage for electrostatic attraction is made low (not greater than 300 V), a sufficient attraction force is not produced and, therefore, it is unable to achieve secure flatness correction of a warped substrate.

As described above, in the semiconductor manufacturing processes, particularly, in an exposure process or the like in which a very fine pattern is processed, even if a substrate such as a wafer has a warp, it should be securely corrected to flat. Furthermore, in the case a manufacturing apparatus uses a vacuum ambience therein, the fact that conventional vacuum attracting mechanisms are unusable and that electric discharge easily takes place in the electrostatic attracting mechanism should be taken into account, and yet safe and secure substrate flatness correction must be done to improve the overlay precision and the throughput.

SUMMARY OF THE INVENTION

It is accordingly an object of the present invention to solve at least one of the inconveniences described above.

In accordance with an aspect of the present invention, to achieve this object, there is provided a substrate holding system having a chuck for vacuum attraction and electrostatic attraction of a substrate, comprising; a ring-like rim for carrying a substrate thereon; a plurality of first protrusions disposed inside said rim, for carrying the substrate thereon; and a plurality of second protrusions disposed inside said rim, for carrying the substrate thereon, wherein a substrate carrying surface area of at least one first protrusion is smaller than a substrate carrying surface area of at least one second protrusion and wherein a smallest interval of the first protrusions is smaller than a smallest interval of the second protrusions.

In accordance with the present invention, flatness correction of a substrate can be stabilized.

These and other objects, features and advantages of the present invention will become more apparent upon a consideration of the following description of the preferred embodiments of the present invention taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view of a structure of a substrate attracting device according to a first embodiment of the present invention.

FIGS. 2A and 2B are sectional views of the structure of the FIG. 1 embodiment.

FIGS. 3A and 3B are schematic views of a structure of a substrate attracting device according to a second embodiment of the present invention.

FIGS. 4A and 4B are schematic and sectional views for explaining the operation of a power supplying system for transfer of a substrate between a conveying hand and a fixed plate, in the structure of FIG. 1.

FIG. 5 is a schematic view of a structure of a substrate attracting device in a substrate correcting device according to a third embodiment of the present invention.

FIG. 6 is a schematic and sectional view of the structure of the substrate correcting device of the third embodiment of the present invention.

FIG. 7 is a schematic and sectional view for explaining a vacuum attraction piping structure in the substrate attracting device of the third embodiment of the present invention.

FIG. 8 illustrates a conventional vacuum attraction piping structure.

FIG. 9 is a schematic and diagrammatic view of a structure of a substrate correcting device in a load look chamber, according to a fourth embodiment of the present invention.

FIG. 10 is a flow chart for explaining the substrate correcting operation in the structure of FIG. 9.

FIG. 11 is a graph of notion of Paschen's electric discharge potential.

FIG. 12 is a flow chart for explaining the sequence of device manufacturing processes.

FIG. 13 is a flow chart for explaining details of a wafer process included in the procedure of FIG. 12.

FIG. 14 is a schematic view of a device manufacturing exposure apparatus.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Preferred embodiments of the present invention will now be described with reference to the attached drawings.

Embodiment 1

FIGS. 1, 2A and 2B illustrate the structure of a substrate attracting device according to a first embodiment of the present invention. In FIG. 1, a substrate attracting portion (chuck) 101 includes protrusions (first protrusions) 102 mainly for electrostatic attraction, protrusions (second protrusions) 103 mainly for vacuum attraction, a ring-like rim 104 adapted to apply vacuum to between the substrate and the substrate attracting portion, and an exhaust port 105. The total area of the substrate carrying surface as defined by the group of protrusions 103 for the vacuum attraction is made larger than the total area of the substrate carrying surface as defined by the group of protrusions 102 for electrostatic attraction. Furthermore, each protrusion 103 for vacuum attraction has a smaller carrying surface area than the protrusion 102 for electrostatic attraction, and also the interval of the protrusions 103 is smaller than that of the protrusions 102. Each of the protrusions 102 and 103 has a height not lower than 50 [im].

In vacuum attraction, attraction forces act on the region other than the contact surface between a substrate 106 (FIGS. 2A and 2B) and the substrate attracting portion 101 (more exactly, the substrate carrying surfaces of the protrusions 102 and 103 and the rim 104). If therefore the interval between the protrusions is wide, the substrate receives a downward force and it is caved downwardly. In this embodiment, since the substrate can be supported at multiple points by means of the protrusions 103 having narrow intervals, deformation of the substrate can be made sufficiently small. Here, for better flatness of the substrate, the substrate carrying surface area of the protrusions 103 as well as the interval of them should desirably be made as small as possible.

In electrostatic attraction, basically the substrate is attracted and held by the contact surface between the substrate 106 and the substrate attracting portion 101 (more exactly, the substrate carrying surfaces of the protrusions 102). Therefore, this contact surface should have a certain area. In this embodiment, a sufficient contact surface area is secured by the protrusions 102 as a whole and, by producing an attraction force to the whole substrate surface, the substrate can be well attracted and held. In order to secure a contact surface area to obtain a sufficient electrostatic attraction force, the surface area of the protrusions 102 should be made as large as possible. However, taking into account the risk of substrate flatness degradation due to increased probability of particle bite, it should be designed appropriately.

With the structure described above, in a substrate attracting device having both of a vacuum attracting mechanism and an electrostatic attracting mechanism, whichever is operated even both are operated, the substrate can be attracted and held to the substrate attracting device with good flatness.

Particularly, as regards a substrate being warped, first the vacuum attracting mechanism may be operated to correct the warp and, subsequently, the electrostatic attracting mechanism may be operated. In that occasion, even if the substrate is moved into a vacuum ambience, the flatness of the corrected substrate can be well maintained.

FIGS. 2A and 2B illustrate a section when a substrate 106 is placed on the substrate attracting device of this embodiment. As regards the material of the substrate attracting portion 101, from the standpoint of rigidity or weight, for example, ceramics such as alumina, AlN, and Sic, for example, may be used as a base material. From the standpoint of thermal expansion, a low thermal expansion material may preferably be used as a base material.

As regards the method of forming protrusions 102 and 103 upon the base material, a blast processing method may be used, for example. Here, as shown in FIG. 2A, the vacuum attraction protrusion 102 having a smaller sectional area may be formed to a depth 50 im or more while keeping a constant sectional area. If however insufficient rigidity is concerned, as shown in FIG. 2B, at some depth the sectional area may be enlarged for increased rigidity.

Embodiment 2

FIGS. 3A, 3B, 4A and 4B illustrate the structure of a substrate attracting device according to a second embodiment of the present invention. In the second embodiment, a substrate attracting portion (chuck) 201 having at least an electrostatic attracting mechanism is provided with a power supply terminal 202 for during conveyance of the substrate attracting portion, and a power supply terminal 203 for during fixation (stationary) of the substrate attracting portion.

FIGS. 3A and 3B shows a power supplying line 206 for the substrate attracting portion 201 when the same is being conveyed by a conveying hand 205. The power supply terminal 202 for during conveyance is provided at a location separate from the power supply terminal 203 for during fixation of the substrate attracting portion, and an electric power is supplied from the power supplying line 206 of the conveying hand 205. The conveying hand 205 may have any arbitrary shape, and also the power supply terminal 202 may be provided at any arbitrary location. However, for convenience of cable setting, it should desirably be provided adjacent a position where the conveying hand 205 grasps the substrate attracting portion 201.

FIGS. 4A and 4B illustrate a power supply line for during transfer of a chuck between the conveying hand 205 and a chuck supporting table 207. In the state illustrated, an electric power can be supplied to the substrate attracting portion 201 from both of a power supplying line 208 from the chuck supporting table 207 and a power supplying line 206 from the conveying hand 205. As regards the chuck supporting table 207, if in an exposure apparatus the substrate attracting portion 201 is held fixed within an exposure chamber (substrate processing chamber), it may be a stage. If the substrate attracting portion is held fixed outside the substrate processing chamber, for example, fixed in a load lock chamber, it may be a supporting table provided there. As shown in FIG. 4A or 4B, the power supplying terminal 203 for during fixation of the substrate attracting portion 201 may be provided at the bottom face of the substrate attracting portion, or it may be provided at any location such as upon a side face of the substrate attracting portion 201, for example.

As described above, in relation to at least one electrode of the substrate attracting portion 201, both of a conveyance-period power supplying terminal 201 and a fixation-period power supplying terminal 203 are prepared. With this structure, an electric power can be supplied from respective power supplying lines 206 and 208. As a result, even if the state of substrate attracting portion 201 changes in an order of fixation, conveyance and fixation, for example, the power can be supplied thereto continuously.

As regards the power supplying terminal, for prevention of electric discharge or for safety, it should desirably be covered by an insulative.

In the structure described above, even if the substrate is warped and flatness correction is not easy, it is possible that the flatness correction is done outside a substrate processing chamber, for example, in a load lock chamber where a relatively wide freedom is available in terms of space and environment, and subsequently the substrate is conveyed into the substrate processing chamber while keeping the corrected flatness. Therefore, an increase of yield resulting from secured flatness correction and an increase of throughput resulting from omission of substrate attracting step inside the substrate processing chamber as well can be achieved.

For better results, three protrusions may desirably be formed on the bottom face of the substrate holding portion 201 to provide a three-point support structure. In that occasion, the same supporting state can be maintained continuously even if the fixing position of the substrate attracting portion is shifted, and therefore a better reproducibility of substrate attracting state and improved overlay precision are assured.

Embodiment 3

FIGS. 5 and 6 illustrate the structure of a substrate correcting device according to a third embodiment of the present invention. In the third embodiment, a substrate attracting portion (chuck) 301 having at least an electrostatic attracting mechanism is provided with electrodes 302 which are arrayed in a stripe-like fashion as shown in FIG. 5, and also, means for applying a voltage to each electrode is provided. Although, in FIG. 5, the shape of other substrate carrying surfaces is defined by protrusions 303 and a ring-like rim 304, any other structure may be used. However, for secured attraction force, it is preferable to provide electrodes throughout the whole carrying surface as much as possible.

In this embodiment, as shown in FIG. 6, there is a chuck rotating mechanism 316 for rotationally moving the chuck 301 to thereby change the orientation of the stripe-like electrodes 302 as desired. In FIG. 6, the rotating mechanism 316 connected to the chuck supporting table 311 placed inside a chamber 315 which may be a substrate processing chamber or a load lock chamber. However, the rotating mechanism may have any other structure, and it ma be provided inside the substrate attracting portion 301.

In the structure described above, when a voltage is applied sequentially to the electrodes, from one at an end in FIG. 5, for example, a warped substrate can be consecutively attracted to the substrate attracting portion from its end portion, by which the substrate can be corrected into flat. Furthermore, by rotating the substrate attracting portion, it can meet correction of irregularly warped substrates. The orientation of the substrate attracting portion may be determined by measuring the warp shape of a substrate beforehand. Alternatively, once a substrate is attracted and, if flatness correction is not good, the orientation is changed by rotation until good flatness correction is enabled.

Embodiment 4

FIG. 7 illustrates a vacuum attraction piping (exhausting labyrinth) structure of a substrate attracting device according to a fourth embodiment of the present invention. In the structure of FIG. 7, in a substrate attracting portion (chuck) 401 having at least a vacuum attracting mechanism, a vacuum exhaust pipe 404 is disposed opposed to an exhaust port 403 for vacuum attraction, inside the substrate attracting portion, with a small clearance intervening therebetween. Also, there is a partition wall 405 which functions to prevent a gas, outside a closed space defined by the substrate attracting portion and the substrate, from flowing into the exhaust port 403 and into that closed space through the small clearance.

The width of the small clearance is set to an extent (about 5 [im], for example) making the conductance of the clearance sufficiently small to prevent inflow of the gas.

Conventionally, for vacuum attraction, a seal member such as O-ring is pressed against the bottom face of a substrate attracting portion or, alternatively, as shown in FIG. 8, an exhaust pipe 414 is directly attached to an exhaust port 413 of the substrate attracting portion 401 while using a seal member such as O-ring 416. In FIG. 8, denoted at 415 is a pipe connecting mechanism. In theses structures, however, since a force can be applied to the substrate attracting portion 401 from the exhaust pipe 414 through the seal member, small distortion may be created in the substrate attracting portion 401. Furthermore, the distortion to be produced in the substrate attracting portion 401 is variable in dependence upon the connection state with the seal member 416. Therefore, the flatness correction state of the substrate 402 can not be reproduced.

In this embodiment, in consideration of it, as shown in FIG. 7, a non-contact vacuum seal structure is provided between the exhaust pipe 404 and the vacuum attracting portion 401, thereby to prevent transmission of a force from the exhaust pipe 404 to the vacuum attracting portion 404. With this arrangement, substrate flatness correction of good reproducibility is achieved.

In the case of a system wherein a substrate attracting portion is made conveyable, simply by placing the substrate attracting portion 401 on the chuck supporting table 406, vacuum seal is enabled. In such occasion, therefore, a mechanism or a step for every time connecting a vacuum pipe to the substrate attracting portion can conveniently be omitted. Furthermore, since no heat is transferred to the substrate attracting portion from the load lock chamber or the like through the vacuum pipe, the structure for preventing thermal deformation of the substrate attracting portion can be omitted or simplified.

These advantageous features function particularly effectively in the structure that the substrate attracting portion 401 is supported on the chuck supporting table 406 by three-point support. Where the substrate attracting portion 401 is supported at three points, although there may occur self-weight deformation in the substrate attracting portion and the flatness of the substrate carrying surface may be degraded, the flatness of the substrate carrying surface can be improved by flattening the same while leaving the self-weight deformation as it is. If it is difficult to perform the flattening while keeping the self-weight deformed condition, depending on the process condition or the like, an appropriate external force may be applied to cause deformation, equivalent to self-weigh deformation, in the substrate attracting portion and them the flattening process may be carried out.

Furthermore, if the vacuum seal effect of the non-contact partition wall 405 should be improved much more, a groove surrounding the exhaust pipe 404 may be formed in the partition wall as disclosed in Japanese Patent No. 2587227, and the groove may be exhausted by means of a vacuum pump or the like. By this, the vacuum seal effect can be enhanced.

Embodiment 5

FIG. 9 illustrates a general structure of a substrate correcting device according to a fifth embodiment of the present invention. The substrate correcting device of FIG. 5 mainly comprises: a substrate attracting portion (chuck) 501 having an electrostatic attracting mechanism and a vacuum attracting mechanism; a power supplying line 507 for operating the electrostatic attracting mechanism; an exhaust port 503 provided in the substrate attracting portion 501, for operating the vacuum attracting mechanism; a vacuum pump 516 for exhausting a clearance between a substrate 502 and the substrate attracting portion 501 and exhausting the load lock chamber 511; a valve 512 of a pipe extending from the vacuum pump 516 to the load lock chamber 511; a valve 513 of a pipe connected to the exhaust port 503; pressure gauges 514 and 515 for measuring the pressure of the clearance between the substrate and the substrate attracting portion and the pressure of the load lock chamber 511, respectively; and a controller 517 for controlling the valves 512 and 513 as well as the vacuum pump 516.

FIG. 10 is a flow chart, illustrating the operation of the structure described above. Initially, a substrate 502 is conveyed onto the substrate attracting portion 501 inside the load lock chamber 511. Then, the valves 512 and 513 are opened and the vacuum pump 516 is actuated, to reduce the pressure inside the load lock chamber 511 and the pressure in the clearance between the substrate 502 and the substrate attracting portion 501 to an appropriate pressure, respectively, simultaneously. The pressure, here, corresponds to a differential pressure necessary for vacuum attracting the substrate 502. If, for example, the appropriate differential pressure for vacuum attraction of a substrate 502 in a certain substrate attracting portion 501 is 30 [kpa], the pressure in the whole is reduced to 30 [kpa]. Subsequently, the load lock chamber valve 512 is closed, and only the clearance between the substrate 502 and the substrate attracting portion 501 is vacuum exhausted, whereby the substrate 502 is vacuum attracted. After it is discriminated that the pressure of the clearance between the substrate 502 and the substrate attracting portion 501 has passed the minimum value of Paschen's discharge potential graph (FIG. 11) and it has reached a pressure level (e.g., 100 Pa) whereat the electric discharge does not easily occur (i.e., discharge potential is sufficiently high), the electrostatic attracting mechanism is actuated by the power supplying line 507 whereby the substrate 502 is electrostatically attracted onto the substrate attracting portion 501.

Thereafter, the valve 513 is closed to prevent back flow of airs into the clearance between the substrate 502 and the substrate attracting portion 501 and, then, the valve 512 is opened to vacuum-exhaust the load lock chamber 511. Here, if the pressure of the clearance between the substrate 502 and the substrate attracting portion 501 can not be maintained constant due to gas leakage or the like, an exclusive vacuum pump may be preferably provided separately to keep that pressure constant. After it is discriminated that the pressure of the load lock chamber 511 has passed the minimum value of Paschen's discharge potential graph (FIG. 11) and it has reached a pressure level whereat the electric discharge does not easily occur (i.e. discharge potential is sufficiently high), the valve 513 is opened and vacuum is applied until the pressure as a whole becomes approximately equal to that of the substrate processing chamber (not greater than 1 Pa). Through these sequential operations, even if a high voltage enabling the flatness correction is applied to the chuck, there is no possibility of electric discharge between the substrate 502 and the substrate attracting portion 501.

Thereafter, the substrate 502 and the substrate attracting portion 501 are conveyed into the substrate processing chamber (not shown), and processing operations for the substrate 501 are initiated. Here, the structure having been described with reference to the second embodiment may be applied, and two or more power supplying systems such as the fixation-period power supplying terminal 508 and the conveyance-period power supplying terminal 509 may be used. With this arrangement, the substrate 502 can be conveyed into the substrate processing chamber while the flatness corrected state is kept secured.

Alternatively, the structure of the substrate carrying surface of the substrate attracting device having been described with reference to the first embodiment may be applied and, by using either one of the vacuum attraction force and the electrostatic attraction force or by using both of them, the substrate can be held in a flatness well-corrected state.

Furthermore, the structure described with reference to the fourth embodiment may be applied, and a partition wall 505 may be provided inside the load lock chamber and a vacuum exhaust pipe 504 ma be connected to the exhaust port 504 without contact thereto. In such structure, the mechanism or steps for connecting a vacuum pipe to the substrate attracting portion every time it is conveyed thereto, can be omitted. Since there is no effect of insulating thermal external disturbance to the substrate attracting portion or no restriction due to the piping, the condition of confinement to the substrate attracting portion inside the load lock chamber and inside the substrate processing chamber can be made equivalent to each other. Therefore, flatness corrected state having a good reproducibility is achieved. This structure is particularly effective when the substrate attracting portion 501 is supported on the chuck supporting table at three points. With this arrangement, the substrate attracting portion can hold the same three-point supported state continuously. Therefore, the substrate attracting state has good reproducibility, and thus the overlay precision and the like is improved significantly.

In accordance with the attraction and conveyance sequence for a substrate and a substrate attracting device such as described hereinbefore, the substrate can be flatness corrected with good reproducibility, while avoiding damage of the substrate or substrate attracting device due to electric discharge. Additionally, the substrate can be conveyed into the substrate processing chamber while the flatness corrected state is maintained securely.

In accordance with the structures of the embodiments described hereinbefore, a substrate can be securely flatness-corrected, and it can be conveyed into a substrate processing chamber while avoiding damage of the substrate or substrate attracting device due to electric discharge and while maintaining the corrected flatness. Therefore, in a device manufacturing apparatus such as an exposure apparatus having a substrate attracting device or a chuck and holding device, the throughput and the substrate positioning precision as well as the overlay precision in the exposure process are improved.

Embodiment 6

Next, referring to FIGS. 12 and 13, an embodiment of a device manufacturing method which uses an exposure apparatus having a substrate attracting device such as described above, will be explained.

FIG. 12 is a flow chart for explaining the procedure of manufacturing various microdevices such as semiconductor chips (e.g., ICs or LSIs), liquid crystal panels, CCDs, thin film magnetic heads or micro-machines, for example. Step 1 is a design process for designing a circuit of a semiconductor device. Step 2 is a process for making a mask on the basis of the circuit pattern design. Step 3 is a process for preparing a wafer by using a material such as silicon. Step 4 is a wafer process which is called a pre-process wherein, by using the thus prepared mask and wafer, a circuit is formed on the wafer in practice, in accordance with lithography. Step 5 subsequent to this is an assembling step which is called a post-process wherein the wafer having been processed at step 4 is formed into semiconductor chips. This step includes an assembling (dicing and bonding) process and a packaging (chip sealing) process. Step 6 is an inspection step wherein an operation check, a durability check an so on, for the semiconductor devices produced by step 5, are carried out. With these processes, semiconductor devices are produced, and they are shipped (step 7).

FIG. 13 is a flow chart for explaining details of the wafer process. Step 11 is an oxidation process for oxidizing the surface of a wafer. Step 12 is a CVD process for forming an insulating film on the wafer surface. Step 13 is an electrode forming process for forming electrodes upon the wafer by vapor deposition. Step 14 is an ion implanting process for implanting ions to the wafer. Step 15 is a resist process for applying a resist (photosensitive material) to the wafer. Step 16 is an exposure process for printing, by exposure, the circuit pattern of the mask on the wafer through the exposure apparatus described above. Step 17 is a developing process for developing the exposed wafer. Step 18 is an etching process for removing portions other than the developed resist image. Step 19 is a resist separation process for separating the resist material remaining on the wafer after being subjected to the etching process. By repeating these processes, circuit patterns are superposedly formed on the wafer.

With these processes, high density microdevices can be manufactured in a reduced cost.

Embodiment 7

FIG. 14 shows an exposure apparatus for device manufacture, having a substrate attracting device as described hereinbefore.

This exposure apparatus is to be used for manufacture of microdevices having a fine pattern formed thereon, such as semiconductor devices (semiconductor integrated circuits, for example), micromachines, or thin-film magnetic heads, for example. In this exposure apparatus, exposure light (which may include visible light, ultraviolet light, EUV light, X-ray, electron beam, and charged particle beam, for example) as an exposure energy supplied from a light source 61 illuminates a reticle R (original), and light from the reticle R is projected onto a semiconductor wafer W (substrate) through a projection system having a projection lens 62 (which may include refractive lens, reflective lens, catadioptric lens system, and charged particle lens, for example), whereby a desired pattern is produced on the substrate.

The exposure apparatus includes a base table 51 having a guide 52 and a linear motor stator 21 fixed thereto. The linear motor stator 21 has a multiple-phase electromagnetic coil, while a linear motor movable element 11 includes a permanent magnet group. The linear motor movable portion 11 is connected as a movable portion 53 to a movable guide 54 (stage), and through the drive of the linear motor M1, the movable guide 54 can be moved in a direction of a normal to the sheet of the drawing. The movable portion 53 is supported by a static bearing 55, taking the upper surface of the base table 51 as a reference, and also by a static bearing 56, taking the side surface of the guide 52 as a reference.

A movable stage 57 which is a stage member disposed to straddle the movable guide 54 is supported by a static bearing 58. This movable stage 57 is driven by a similar linear motor M2, so that the movable stage 57 moves leftwardly and rightwardly as viewed in the drawing, while taking the movable guide 54 as a reference. The motion of the movable stage 57 is measured by means of an interferometer 60 and a mirror 59 which is fixed to the movable stage 59.

A wafer (substrate) W is held on a chuck which is mounted on the movable stage 57, and a pattern of the reticle R is transferred in a reduced scale onto different regions on the wafer W by means of the light source 61 and the projection optical system 62, in accordance with a step-and-repeat method or a step-and-scan method.

It should be noted that the substrate attracting device described hereinbefore can be similarly applied also to an exposure apparatus in which, without using a mask, a circuit pattern is directly drawn on a semiconductor wafer to expose a resist thereon.

The present invention can be embodied in various aspects, and examples are as follows.

(1) A substrate attracting device having a substrate attracting portion including a vacuum attracting mechanism and an electrostatic attracting mechanism, characterized in that said substrate attracting portion has a substrate carrying surface defined by at least a ring-like rim and first and second protrusion groups, each protrusion of the first protrusion group has a carrying surface area and a minimum protrusion interval larger than those of each protrusion of the second protrusion group.

(2) A substrate attracting device according to Item (1), wherein a total area of the substrate carrying surface defined by the first protrusion group is larger than a total area of the substrate carrying surface defined by the second protrusion group.

(3) A substrate attracting device according to Item (1) or (2), wherein the first protrusion group is mainly for electrostatic attraction, while the second protrusion group is mainly for vacuum attraction.

(4) A substrate attracting device according to any one of Items (1)-(3), wherein the first protrusion group is protrusions mainly for attracting and holding the substrate during electrostatic attraction, and the second protrusion group is protrusions mainly for suppressing flexure of the substrate during vacuum attraction.

(5) A substrate attracting device according to any one of Items (1)-(4), wherein each of the first and second protrusion groups has a height not lower than 50 im.

(6) A substrate attracting device having a substrate attracting portion including an electrostatic attracting mechanism, characterized by an electrode for electrostatic attraction and having two or more power supplying terminals at the substrate attracting portion.

(7) A substrate attracting device according Item (6), wherein, to the two or more power supplying terminals, electric powers are supplied from separate power supplying systems.

(8) A substrate attracting device according to Item (6) or (7), wherein the two power supplying terminals are for during movement of the substrate attracting portion and for during stationary fixation of the substrate attracting portion, respectively.

(9) A substrate attracting device according to any one of Items (6)-(8), wherein the two power supplying terminals are a power supplying terminal to which an electric power is supplied from a conveying system for conveying the substrate attracting portion, and a power supplying terminal to which an electric power is supplied from a chamber or a stage.

(10) A substrate attracting device according to any one of Items (6)-(9), wherein, when a substrate is placed on the substrate attracting portion, said electrostatic attracting mechanism is continuously energized through the two or more power supplying terminals.

(11) A substrate attracting device having an electrostatic attracting mechanism, characterized by a substrate attracting portion having a plurality of electrostatic attraction electrodes disposed in a stripe-like fashion, means for applying a voltage to said plurality of electrodes independently of each other, and a mechanism for relatively rotating said substrate attracting portion relative to a substrate to be attracted by said substrate attracting portion.

(12) A substrate attracting device according to Item (11), wherein the substrate attracting portion is rotated in a direction effective to correct the flatness of the substrate.

(13) A substrate attracting device according to Item (11) or (12), wherein the substrate attracting portion is rotated in a horizontal direction.

(14) A substrate attracting device according to any one of Items (11)-(13), wherein the substrate attracting portion is rotated outside a substrate processing chamber where a predetermined process is to be performed to the substrate attracted to the substrate attracting portion.

(15) A substrate attracting device, characterized by a substrate attracting portion having a vacuum attracting mechanism, a vacuum exhaust pipe disposed opposed to a vacuum exhaust port formed in said substrate attracting portion, with a small clearance intervening therebetween, and a partition wall effective to prevent inflow of a gas outside the substrate attracting portion through the small clearance.

(16) A substrate attracting device according Item (15), wherein said partition wall is disposed at a position out of contact to the substrate attracting portion, and wherein there is an exhaust mechanism for exhausting a space between the substrate attracting portion and said partition wall.

(17) A substrate attracting device according to Item (15) or (16), wherein the substrate attracting portion is made conveyable.

(18) A substrate attracting device according to any one of Items (15)-(17), wherein the vacuum exhaust pipe and the partition wall are provided outside a substrate processing chamber where a predetermined process is to be carried out to the substrate attracted to the substrate attracting portion.

(19) A substrate attracting device having a substrate attracting portion including an electrostatic attracting mechanism, characterized by control means operable so that, when the substrate is attracted to the substrate attracting portion, a peripheral portion of the substrate and a clearance between the substrate and the substrate attracting portion are depressurized and thereafter only the clearance between the substrate and the substrate attracting portion is further depressurized, and subsequently the electrostatic attracting mechanism is actuated.

(20) A substrate attracting device according to Item (19), wherein said substrate attracting portion includes a vacuum attracting mechanism, and wherein said control means includes an exhaust system in which a vacuum applying pipe for the periphery of the substrate and a vacuum attracting pipe of said vacuum attracting mechanism are communicated with each other.

(21) A substrate attracting device according to Item (19) or (20), wherein said control means includes a measuring device for measuring pressures in the periphery of the substrate and in the clearance between the substrate and the substrate attracting portion.

(22) A substrate attracting device according to any one of Items (1)-(21), wherein there is a base member for supporting the substrate attracting portion at three points.

(23) A substrate attracting device according to Item (22), wherein the substrate attracting portion as supported by said base member at three points has been flattened in a state of deformation defined while being supported by the three points.

(24) A chuck for holding a substrate through vacuum attraction and electrostatic attraction, characterized by a plurality of first protrusions for electrostatic attraction of the substrate, and a plurality of second protrusions provided between said first protrusions, for supporting the substrate.

(25) A chuck according to Item (24), further characterized by a terminal for receiving an electric power during conveyance.

(26) A holding device for holding a chuck as recited in Item (24) or (25), characterized by exhausting means for vacuum attracting the substrate on said chuck, and power supplying means for electrostatically attracting the substrate on said chuck.

(27) A holding device according to Item (26), wherein said exhausting means exhausts the clearance between the chuck and the substrate without contact to the chuck.

(28) A holding device according to Item (27), wherein said power supplying means supplies an electric power on the basis of the pressure in the clearance.

(29) An exposure apparatus characterized by including a substrate attracting device as recited in any one of Items (1)-(23) or a holding device as recited in any one of Items (26)-(28).

(30) A device manufacturing method, characterized by producing a device by use of an exposure apparatus as recited in Item (29).

While the invention has been described with reference to the structures disclosed herein, it is not confined to the details set forth and this application is intended to cover such modifications or changes as may come within the purposes of the improvements or the scope of the following claims.

This application claims priority from Japanese Patent Application No. 2003-343676 filed Oct. 1, 2003, for which is hereby incorporated by reference. 

1. A substrate holding system having a chuck for vacuum attraction and electrostatic attraction of a substrate, comprising: a ring-like rim for carrying a substrate thereon; a plurality of first protrusions disposed inside said rim, for carrying the substrate thereon; and a plurality of second protrusions disposed inside said rim, for carrying the substrate thereon, wherein a substrate carrying surface area of at least one first protrusion is smaller than a substrate carrying surface area of at least one second protrusion and wherein a smallest interval of the first protrusions is smaller than a smallest interval of the second protrusions.
 2. A substrate holding system according to claim 1, wherein a total surface area of the substrate carrying surfaces of the first protrusions is smaller than a total surface area of the substrate carrying surfaces of the second protrusions.
 3. A substrate holding system according to claim 1, wherein each of the first and second protrusions has a height not lower than 50 im.
 4. A substrate holding system according to claim 1, further comprising an electrode for electrostatic attraction and a plurality of terminals for supplying a power to said electrode.
 5. A substrate holding system according to claim 4, wherein said terminals are provided at a side face and a bottom face of said chuck.
 6. A substrate holding system according to claim 1, further comprising a plurality of electrodes for electrostatic attraction, and being provided in a stripe-like fashion.
 7. A substrate holding system according to claim 1, further comprising an exhaust port.
 8. A substrate holding system according to claim 4, further comprising a conveying system for supplying a power to one of said terminals and for conveying said chuck, and a table for supplying a power to another terminal and for supporting said chuck.
 9. A substrate holding system according to claim 6, further comprising a power supplying system for applying voltages to said plurality of electrodes independently of each other, and a mechanism for rotationally moving said chuck.
 10. A substrate holding system according to claim 7, further comprising an exhaust pipe disposed opposed to said exhaust port with a clearance interposed therebetween, and a partition wall provided around said exhaust pipe and disposed opposed to said chuck with a clearance interposed therebetween.
 11. A substrate holding system according to claim 10, further comprising an exhaust mechanism for exhausting the clearance between said partition wall and said chuck.
 12. A substrate holding system according to claim 1, further comprising an exhaust system for exhausting a clearance between said chuck and the substrate, an electrode for electrostatic attraction and being provided in said chuck, a power supplying system for supplying a power to said electrode, a measuring system for measuring a pressure in the clearance, and a control system for controlling the power supply of said power supplying system on the basis of the measurement made by said measuring system.
 13. A substrate holding system according to claim 12, wherein said control system operates to initiate the power supply after the pressure measured by said measuring system becomes lower than a pressure with which a discharge generating voltage takes a minimum value.
 14. A substrate holding system according to claim 1, further comprising an exposure system for exposing a substrate held by said chuck, to a pattern.
 15. A device manufacturing method, comprising the steps of: exposing a substrate to a pattern by use of a substrate holding system as recited in claim 14; and developing the exposed substrate.
 16. A method of holding a substrate in a chamber by use of a substrate holding system as recited in claim 1, said method comprising the step of: exhausting a clearance between the chuck and the substrate; supplying a power to an electrode for electrostatic attraction, being provided in the chuck, after a pressure of the clearance reaches a first pressure lower than a pressure with which a discharge generating voltage takes a minimum value; and exhausting the chamber after the power supply, so that a second pressure lower than the first pressure is produced therein. 